Synthesized, surface-functionalized, acidified metal oxide materials for energy storage, catalytic, photovoltaic and sensor applications

ABSTRACT

An acidified metal oxide (“AMO”) material, preferably in monodisperse nanoparticulate form 20 nm or less in size, having a pH&lt;7 when suspended in a 5 wt % aqueous solution and a Hammett function H 0 &gt;−12, at least on its surface. The AMO material is useful in applications such as a battery electrode, catalyst, or photovoltaic component.

CROSS-REFERENCE TO CO-PENDING APPLICATIONS

This application claims the benefit of U.S. Ser. No. 15/352,388, filed on Nov. 15, 2016, which in turn claimed the benefit of U.S. 62/256,065 and 62/256,059, both filed on Nov. 16, 2015, and incorporated by reference herein.

BACKGROUND OF THE INVENTION

This invention is in the field of materials useful in chemical energy storage and power devices such as, but not limited to, batteries. More specifically, the invention relates to synthesized, acidified metal oxide (“AMO”) nanomaterials for use in applications such as electrochemical cell materials (batteries), catalysts, photovoltaic components, and sensors.

Metal oxides are compounds in which oxygen is bonded to metal, having a general formula M_(m)O_(x). They are found in nature but can be artificially synthesized. In synthetic metal oxides the method of synthesis can have broad effects on the nature of the surface, including its acid/base characteristics. A change in the character of the surface can alter the properties of the oxide, affecting such things as its catalytic activity and electron mobility. The mechanisms by which the surface controls reactivity, however, are not always well characterized or understood. In photocatalysis, for example, the surface hydroxyl groups are thought to promote electron transfer from the conduction band to chemisorbed oxygen molecules.

Despite the importance of surface characteristics, the metal oxide literature, both scientific papers and patents, is largely devoted to creating new, nanoscale, crystalline forms of metal oxides for improved energy storage and power applications. Metal oxide surface characteristics are ignored and, outside of the chemical catalysis literature, very little innovation is directed toward controlling or altering the surfaces of known metal oxides to achieve performance goals.

The chemical catalysis literature is largely devoted to the creation of “superacids”—acidity greater than that of pure sulfuric acid (18.4 M H₂SO₄)—often used for large-scale reactions such as hydrocarbon cracking. Superacidity cannot be measured on the traditional pH scale, and is instead quantified by Hammet numbers. Hammet numbers (Ho) can be thought of as extending the pH scale into negative numbers below zero. Pure sulfuric acid has an H₀ of −12.

There are, however, many reaction systems and many applications for which superacidity is too strong. Superacidity may, for example, degrade system components or catalyze unwanted side reactions. However, acidity may still be useful in these same applications to provide enhanced reactivity and rate characteristics or improved electron mobility.

The battery literature teaches that acidic groups are detrimental in batteries, where they can attack metal current collectors and housings and cause deterioration in other electrode components. Further, the prior art teaches that an active, catalytic electrode surface leads to electrolyte decomposition which can result in gas generation within the cell and ultimately in cell failure.

A need exists for a synthetic metal oxide that is acidic but not superacidic at least on its surface.

SUMMARY OF THE INVENTION

A material according to this invention is a synthesized, acidified metal oxide (“AMO”), preferably in monodisperse nanoparticulate form 20 nm or less in size, having a pH<7 when suspended in a 5 wt % aqueous solution and a Hammett function H₀>−12, at least on its surface. The AMO material is useful in applications such as a battery electrode, catalyst, photovoltaic component, or sensor.

Preferably, synthesis and surface functionalization are accomplished in a “single-pot” hydrothermal method in which the surface of the metal oxide is functionalized as the metal oxide is being synthesized from appropriate precursors. This single-pot method does not require any additional step or steps for acidification beyond those required to synthesize the metal oxide itself, and results in an AMO material having the desired surface acidity (but not superacidic).

In a preferred embodiment, surface functionalization occurs using strong electron-withdrawing groups (“EWGs”)—such as SO₄, PO₄, or halogens—either alone or in some combination with one another. Surface functionalization may also occur using EWGs that are weaker than SO₄, PO₄, or halogens. For example, the synthesized metal oxides may be surface-functionalized with acetate (CH₃COO), oxalate (C₂O₄), and citrate (C₆H₅O₇) groups.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows differences in the cyclic voltammagram of AMO tin prepared by the method disclosed herein relative to that of commercially available, non-AMO tin when cycled against Li.

FIG. 2 shows the total reflectance of AMO tin oxide is different than that of commercially available, non-AMO tin oxide.

FIG. 3 is X-ray photoelectron spectroscopy (XPS) data showing surface functionalization arising endogeneously from the synthesis method disclosed herein. Numbers shown are atomic concentrations in %. The far right column lists the corresponding pH of the synthesized nanoparticles as measured when dispersed at 5 wt % in aqueous solution.

FIG. 4 shows differences in morphology between AMO nanoparticles synthesized under identical conditions except for the use of a different group for functionalization.

FIG. 5 shows the difference in morphology and performance of AMO nanoparticles synthesized under identical conditions except for having two different total reaction times.

FIG. 6 is representative half-cell data showing differences in behavior between spherical and elongated (needle-like or rod-like) AMOs upon cycling against lithium.

FIG. 7 is X-ray photoelectron spectroscopy analysis of the surface of AMO nanoparticles synthesized using both a strong (phosphorous containing) and weak (acetate) electron withdrawing group shows greater atomic concentration of phosphorous than of the bonds associated with acetate groups.

FIG. 8A shows an AMO which was more active than another AMO in visible light.

FIG. 8B shows an AMO which was more active than other AMOs in ultraviolet light.

FIG. 9 is a graph comparing two AMOs, one having higher capacity for use in a primary (single use) battery application and the other having higher cyclability for use in a secondary (rechargeable) battery application.

FIG. 10 shows AMOs can result in enhanced battery performance, without deterioration of battery components or gas generation.

DEFINITIONS

For the purposes of this disclosure, the following terms have the following meanings:

Acidic oxide—a term used generally in the scientific literature to refer to binary compounds of oxygen with a nonmetallic element. An example is carbon dioxide, CO₂. The oxides of some metalloids (e.g., Si, Te, Po) also have weakly acidic properties in their pure molecular state.

Acidified metal oxide (“AMO”)—a term used here to denote a binary compound of oxygen with a metallic element which has been synthesized or modified to have an acidity greater than that of its natural mineralogical state and also a Hammet function, H₀>−12 (not superacidic). The average particle size is also less than that of the natural mineralogical state. Naturally occurring mineralogical forms do not fall within the scope of the inventive AMO material. A synthesized metal oxide, however, that is more acidic than its most abundant naturally occurring mineralogical form (of equivalent stoichiometry) but not superacidic falls within the bounds of this disclosure and can be said to be an AMO material provided it satisfies certain other conditions discussed in this disclosure.

Acidic—a term used generally in the scientific literature to refer to compounds having a pH of less than 7 in aqueous solution.

Electron-withdrawing group (“EWG”)—an atom or molecular group that draws electron density towards itself. The strength of the EWG is based upon its known behavior in chemical reactions. Halogens, for example are known to be strong EWGs. Organic acid groups such as acetate are known to be weakly electron withdrawing.

Hammet function—An additional means of quantifying acidity in highly concentrated acid solutions and in superacids, the acidity being defined by the following equation: H₀=pK_(BH+)+log([B]/[BH+]). On this scale, pure 18.4 molar H₂SO₄ has a H₀ value of −12. The value H₀=−12 for pure sulfuric acid must not be interpreted as pH=−12, instead it means that the acid species present has a protonating ability equivalent to H₃O⁺ at a fictitious (ideal) concentration of 10¹² mol/L, as measured by its ability to protonate weak bases. The Hammett acidity function avoids water in its equation. It is used herein to provide a quantitative means of distinguishing the AMO material from superacids. The Hammet function can be correlated with colorimetric indicator tests and temperature programmed desorption results.

Metal oxide—a term used generally in the scientific literature to refer to binary compounds of oxygen with a metallic element. Depending on their position in the periodic table, metal oxides range from weakly basic to amphoteric (showing both acidic and basic properties) in their pure molecular state. Weakly basic metal oxides are the oxides of lithium, sodium, magnesium, potassium, calcium, rubidium, strontium, indium, cesium, barium and tellurium. Amphoteric oxides are those of beryllium, aluminum, gallium, germanium, astatine, tin, antimony, lead and bismuth.

Monodisperse—characterized by particles of uniform size which are substantially separated from one another, not agglomerated as grains of a larger particle.

pH—a functional numeric scale used generally in the scientific literature to specify the acidity or alkalinity of an aqueous solution. It is the negative of the logarithm of the concentration of the hydronium ion [H₃O⁺]. As used here it describes the relative acidity of nanoparticles suspended in aqueous solution.

Surface functionalization—attachment of small atoms or molecular groups to the surface of a material.

Superacid—substances that are more acidic than 100% H₂SO₄, having a Hammet function, H₀<−12.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The preferred embodiments described here provide illustrative examples of acidified metal oxides (“AMOs”) materials useful in applications such as a battery electrode, catalyst, or photovoltaic component. The surface of these AMO materials is acidic but not superacidic.

The surfaces of metal oxides are ideally arrays of metal and oxygen centers, ordered according to the crystalline structure of the oxide. In reality the arrays are imperfect, being prone to vacancies, distortion, and the effects of surface attachments. Regardless, any exposed metal centers are cationic (positively charged) and can accept electrons, thus functioning by definition as Lewis acid sites. Oxygen centers are anionic (negatively charged) and act as Lewis base sites to donate electrons. This leads to the well-known amphotericity of metal oxide surfaces.

Under normal atmospheric conditions, the presence of water vapor will adsorb to the metal oxide surface either molecularly (hydration) or dissociatively (hydroxylation). Both OH− and H+ species can adsorb on the oxide surface. The negatively-charged hydroxyl species will attach at the metal, cationic (Lewis acid, electron accepting) centers, and the H+ will attach at the oxygen, anionic (Lewis base, electron donating) centers. Both adsorptions lead to the presence of the same functional group—a hydroxyl—on the metal oxide surface.

These surface hydroxyl groups can serve as either Brønsted acids or as Brønsted bases, because the groups can either give up or accept a proton. The tendency of an individual hydroxyl group to be a proton donor or a proton acceptor is affected by the coordination of the metal cation or oxygen anion to which it is attached. Imperfections of the metal oxide surface such as oxygen vacancies, or coordination of the surface groups with other chemical species, mean that all cations and anions are not equally coordinated. Acid-base sites will vary in number and in strengths. When broadly “totaled” across the surface of the oxide, this can give the surface an overall acidic or basic character.

The quantity and strength of Lewis acid and base sites—from the exposed metal cations and oxygen anions, respectively) and Brønsted acid and base sites (from the surface hydroxyl groups)—add broad utility and functionality to the metal oxide and its use in both chemical reactions and device applications. The sites are a strong contributor to the chemical reactivity of the metal oxide. They can serve as anchor sites to which other chemical groups, and even additional metal oxides, may be attached. And they can affect surface charge, hydrophilicity and biocompatibility.

One way of altering the surface of metal oxides is to attach small chemical groups or electron-withdrawing groups (“EWGs”) in a process known as surface functionalization. The EWG induces polarization of the hydroxide bonds and facilitates dissociation of hydrogen. For example, a stronger EWG should lead to a more polarized bond and therefore a more acidic proton. The acidity of Lewis sites can be increased by inducing polarization that facilitates the donation of electrons to the site. When compounds so made are placed in water, the acidic protons will dissociate and so reduce the aqueous pH measurement.

Though somewhat imprecise when working with solid acid/base systems rather than liquid ones, traditional methods of pH measurement utilizing titrations, pH paper and pH probes can be used to evaluate the acidity of metal oxides dispersed in aqueous solution. These measurements can be supplemented by the use of techniques including but not limited to colorimetric indicators, infrared spectroscopy, and temperature programmed desorption data to establish the acidified nature of the metal oxide surface. Surface groups can be examined by standard analytical techniques including but not limited to x-ray photoelectron spectroscopy.

Surface functionalization can be accomplished post-synthesis, including but not limited to exposing the metal oxide to acidic solutions or to vapors containing the desired functional groups. It can also be accomplished via solid state methods, in which the metal oxide is mixed and/or milled with solids containing the desired functional groups. However, all of these methods require an additional surface functionalization step or steps beyond those required to synthesize the metal oxide itself.

Synthesis and surface functionalization of the AMO material may be accomplished in a “single-pot” hydrothermal synthesis method or its equivalent in which the surface of the metal oxide is functionalized as the metal oxide is being synthesized from appropriate precursors. A precursor salt containing an EWG is solubilized and the resulting solution is acidified using an acid containing a second EWG. This acidified solution is then basified and the basified solution is heated then washed. A drying step produces the solid AMO material.

By way of example, a preferred embodiment of an AMO form of tin oxide was synthesized and simultaneously surface functionalized using the following single-pot method:

-   -   1. Initially, seven grams (7 g) of a tin (II) chloride dihydrate         (SnCl₂ 2H₂O) is dissolved in a solution of 35 mL of absolute         ethanol and 77 mL distilled water.     -   2. The resulting solution is stirred for 30 minutes.     -   3. The solution is acidified by the addition of 7 mL of 1.2M         HCl, added dropwise, and the resulting solution is stirred for         15 minutes.     -   4. The solution is basified by the addition of 1M of an aqueous         base, added dropwise until the pH of the solution is about 8.5.     -   5. The resulting opaque white suspension is then placed in a         hot-water bath (˜60° to 90° C.) for at least 2 hours while under         stirring.     -   6. The suspension is then washed with distilled water and with         absolute ethanol.     -   7. The washed suspension is dried at 100° C. for 1 hour in air         and then annealed at 200° C. for 4 hours in air.         This method results in an AMO of tin, surface-functionalized         with chlorine, whose pH is approximately 2 when measured in an         aqueous solution at 5 wt % and room temperature. By definition         its Hammet function, H₀>−12. Although an open system such as a         flask is described here, a closed system such as an autoclave         may also be used.

A person skilled in the art would recognize the method's parameters can be varied as is typical in hydrothermal synthesis. These parameters include, but are not limited to, type and concentration of reagents, type and concentration of acid and base, reaction time, temperature and pressure, stir rate and time, number and types of washing steps, time and temperature of drying and calcination, and gas exposure during drying and calcination. Variations may be conducted singly, or in any combination, preferably using experimental design methodologies. Additionally, other metal oxide synthesis methods—e.g., spray pyrolysis methods, vapor phase growth methods, electrodeposition methods, solid state methods, and hydro- or solvo thermal process methods—might be adaptable to achieve the same or similar results as the method disclosed here.

The performance characteristics of the AMO nanomaterial differ from those of non-acidified metal oxide nanoparticles. As one example, FIG. 1 shows differences in the cyclic voltammagram of AMO tin prepared by the single-pot method relative to that of commercially available, non-AMO tin when cycled against Li. As another example, FIG. 2 shows the total reflectance of AMO tin oxide is different than that of commercially available, non-AMO tin oxide. The data indicates that the AMO has a lower band gap and therefore more desirable properties as a component of a photovoltaic system.

The AMO material may be thought of as having the general formula

M_(m)O_(x)/G

where

-   -   M_(m)O_(x) is the metal oxide, m being at least 1 and no greater         than 5, x being at least 1 and no greater than 21;     -   G is at least one EWG that is not hydroxide, and     -   / simply makes a distinction between the metal oxide and the         EWG, denoting no fixed mathematical relationship or ratio         between the two.         G may represent a single type of EWG, or more than one type of         EWG.

The preferred AMOs are acidified tin oxides (SnxO_(y)), acidified titanium dioxides (Ti_(a)O_(b)), acidified iron oxides (Fe_(c)O_(d)), and acidified zirconium oxide (Zr_(e)O_(f)). Preferred electron-withdrawing groups (“EWGs”) are Cl, Br, BO₃, SO₄, PO₄ and CH₃COO. Regardless of the specific metal or EWG, the AMO material is acidic but not superacidic, yielding a pH<7 when suspended in an aqueous solution at 5 wt % and a Hammet function, H₀>−12, at least on its surface.

The AMO material structure may be crystalline or amorphous (or a combination thereof), and may be utilized singly or as composites in combination with one another, with non-acidified metal oxides, or with other additives, binders, or conductive aids known in the art. The AMO material may be added to a conductive aid material such as graphite or conductive carbon (or their equivalents) in a range of 10 wt % to 80 wt % and upwards of 90 wt % to 95 wt %. In preferred embodiments, the AMO was added at 10 wt %, 33 wt %, 50 wt %, and 80 wt %.

To maximize the amount of overall surface area available, the AMO should be in nanoparticulate form (i.e., less than 1 micron in size) and substantially monodispersed. More preferably, the nanoparticulate size is less than 100 nm and, even more preferably, less than 20 nm or 10 nm.

Mixed-metal AMOs, in which another metal or metal oxide is present in addition to the simple, or binary oxide, also have been reduced to practice. These mixed-metal AMOs may be thought of as having the general formula

M_(m)N_(n)O_(x)/G and M_(m)N_(n)R_(r)O_(x)/G

where:

-   -   M is a metal and m is at least 1 and no greater than 5;     -   N is a metal and n is greater than zero and no greater than 5;     -   R is a metal and r is greater than zero and no greater than 5;     -   O is total oxygen associated with all metals and x is at least 1         and no greater than 21;     -   / simply makes a distinction between the metal oxide and the         electron-withdrawing surface group, denoting no fixed         mathematical relationship or ratio between the two; and     -   G is at least one EWG that is not hydroxide.         G may represent a single type of EWG, or more than one type of         EWG.

Some prior art mixed metal oxide systems, of which zeolites are the most prominent example, display strong acidity even though each simple oxide does not. Preferred embodiments of the mixed-metal AMO of this disclosure differ from those systems in that any embodiment must include at least one AMO which is acidic (but not superacidic) in simple M_(m)O_(x)/G form. Preferred mixed metal and metal oxide systems are Sn_(x)Fe_(c)O_(y+d) and Sn_(x)Ti_(a)O_(y+b), where y+d and y+b may be an integer or non-integer value.

In a preferred embodiment, the mixed metal AMO material is produced via the single-pot method with one modification: synthesis begins with two metal precursor salts rather than one, in any proportion. For example, Step 1 of the single-pot method may be altered as follows: Initially, 3.8 g of tin (II) chloride dihydrate (SnCl₂ 2H₂O) and 0.2 g of lithium chloride (LiCl) are dissolved in a solution of 20 mL of absolute ethanol and 44 mL distilled water.

Three metal precursor salts could also be used, in any proportion. The metal precursor salts could have the same or differing anionic groups, depending on the desired product; could be introduced at different points in the synthesis; or could be introduced as solids or introduced in a solvent.

Experimentation with the single-pot method led to seven key findings. First, in all cases both surface functionalization and acidity arise endogenously (see FIG. 3), rather than created post-synthesis. Unlike prior art surface functionalization methods, the single-pot method does not require any additional step or steps for surface functionalization beyond those required to synthesize the metal oxide itself, nor does it make use of hydroxyl-containing organic compounds or hydrogen peroxide.

Second, the method is broadly generalizable across a wide range of metal oxides and EWGs. Using the method, metal oxides of iron, tin, antimony, bismuth, titanium, zirconium, manganese, and indium have been synthesized and simultaneously surface-functionalized with chlorides, sulfates, acetates, nitrates, phosphates, citrates, oxalates, borates, and bromides. Mixed metal AMOs of tin and iron, tin and manganese, tin and manganese and iron, tin and titanium, indium and tin, antimony and tin, aluminum and tin, lithium and iron, and lithium and tin also have been synthesized. Additionally, surface functionalization can be accomplished using EWGs that are weaker than halogens and SO₄ yet still produce acidic but not superacidic surfaces. For example, the method also has been used to synthesize AMOs surface-functionalized with acetate (CH₃COO), oxalate (C₂O₄), and citrate (C₆H₅O₇).

Third, there is a synergistic relationship between the EWG and other properties of the nanoparticles such as size, morphology (e.g., plate-like, spherical-like, needle- or rod-like), oxidation state, and crystallinity (amorphous, crystalline, or a mixture thereof). For example, differences in morphology can occur between AMO nanoparticles synthesized under identical conditions except for the use of a different EWG for surface functionalization (see FIG. 4). The surface functionalization may act to “pin” the dimensions of the nanoparticles, stopping their growth. This pinning may occur on only one dimension of the nanoparticle, or in more than one dimension, depending upon exact synthesis conditions.

Fourth, the character of the AMO is very sensitive to synthesis conditions and procedures. For example, differences in morphology and performance of the AMO's nanoparticles can occur when synthesized under identical conditions except for having two different total reaction times (see FIGS. 5 & 6). Experimental design methodologies can be used to decide the best or optimal synthesis conditions and procedures to produce a desired characteristic or set of characteristics.

Fifth, both the anion present in the precursor salt and the anion present in the acid contribute to the surface functionalization of the AMO. In one preferred embodiment, tin chloride precursors and hydrochloric acid are used in a synthesis of an AMO of tin. The performance of these particles differ from an embodiment in which tin chloride precursors and sulfuric acid are used, or from an embodiment in which tin sulfate precursors and hydrochloric acid are used. Therefore, matching the precursor anion and acid anion is preferred.

Sixth, when utilizing a precursor with a weak EWG and an acid with a strong EWG, or vice versa, the strongly withdrawing anion will dominate the surface functionalization. This opens up a broader range of synthesis possibilities, allowing functionalization with ions that are not readily available in both precursor salts and acids. It may also permit mixed functionalization with both strong and weak EWGs. In one example, a tin acetate precursor and phosphoric acid are used to synthesize an AMO of tin. X-ray photoelectron spectroscopy analysis of the surface shows a greater atomic concentrations of phosphorous than of the bonds associated with acetate groups (see FIG. 7).

Seventh, and last, while the disclosed method is a general procedure for synthesis of AMOs, the synthesis procedures and conditions may be adjusted to yield sizes, morphologies, oxidation states, and crystalline states as are deemed to be desirable for different applications. As one example, catalytic applications might desire an AMO material which is more active in visible light (see FIG. 8A) or one which is more active in ultraviolet light (see FIG. 8B).

In another example, the AMO material may be used as a battery electrode. A primary (single-use) battery application might desire an AMO with characteristics that lead to the highest capacity, while a secondary (rechargeable) battery application might desire the same AMO but with characteristics that lead to the highest cyclability (see FIG. 9). The AMO material can result in enhanced battery performance, without deterioration of battery components or gas generation (see FIG. 10). This is exactly opposite what the prior art teaches. 

What is claimed:
 1. A battery electrode nanomaterial comprising: a non-soluble solid metal oxide having a particle dimension no greater than 20 nm and having, at least on its surface, a pH<5.5 and a Hammet function H₀>−12; the non-soluble solid metal oxide being in a dried form after synthesis, the pH being measured when the dried form is re-suspended in water at 5 wt %.
 2. A battery electrode nanomaterial according to claim 1, the non-soluble solid metal oxide being tin oxide.
 3. A battery electrode nanomaterial according to claim 2, the tin oxide having a lithiation capacity of at least 1400 mAh/g.
 4. A battery electrode nanomaterial according to claim 2, the tin oxide having a lithiation capacity of at least 1300 mAh/g.
 5. A battery electrode nanomaterial according to claim 2, the tin oxide having a lithiation capacity of at least 1200 mAh/g.
 6. A battery electrode nanomaterial according to claim 2, the tin oxide having a lithiation capacity of at least 1100 mAh/g.
 7. A battery electrode nanomaterial according to claim 2, the tin oxide having a lithiation capacity of at least 1000 mAh/g.
 8. A battery electrode nanomaterial according to claim 2, the tin oxide having a lithiation capacity of at least 900 mAh/g.
 9. A battery electrode nanomaterial according to claim 2, the tin oxide having a lithiation capacity>800 mAh/g.
 10. A battery electrode nanomaterial according to claim 1, the non-soluble solid metal oxide being surface functionalized with at least one electron-withdrawing group, the at least one electron-withdrawing group having a molecular weight less than
 200. 11. A battery electrode nanomaterial according to claim 1, the non-soluble solid metal oxide being surface functionalized with at least one electron the at least one electron-withdrawing surface group having a carbon chain length no greater than
 4. 12. A battery electrode nanomaterial according to claim 1, the pH<5.
 13. A battery electrode nanomaterial according to claim 1, the pH<4.5.
 14. A battery electrode nanomaterial according to claim 1, the pH<4.
 15. A battery electrode nanomaterial according to claim 1, the pH<3.5.
 16. A battery electrode nanomaterial according to claim 1, the pH<3.
 17. A battery electrode nanomaterial according to claim 1, the pH<2.5
 18. A battery electrode nanomaterial according to claim 1, the pH<2.0.
 19. A battery electrode nanomaterial according to claim 1 further comprising the particle dimension being less than 10 nm.
 20. A battery electrode nanomaterial according to claim 1, the non-soluble solid metal oxide being iron oxide.
 21. A battery electrode nanomaterial according to claim 1, the non-soluble solid metal oxide being in substantially monodispersed nanoparticulate form.
 22. A battery electrode nanomaterial according to claim 1, wherein the battery electrode nanomaterial is configured as an anode.
 23. A battery electrode non-soluble solid metal oxide nanomaterial, the non-soluble solid metal oxide being in a form M_(m)O_(x)/G, where M_(m) is a metal, m is at least 1 and no greater than 5; O_(x) is total oxygen, x is at least 1 and no greater than 21; M_(m)O_(x) is a metal oxide; G is at least one electron-withdrawing surface group, and “/” makes a distinction between the metal oxide and the electron-withdrawing surface group. the non-soluble solid metal oxide nanomaterial having, at least on its surface, a pH <5.5 and a Hammet function H₀>−12; the non-soluble solid metal oxide nanomaterial being in a dried form after synthesis, the pH being measured when the dried form is re-suspended in water at 5 wt %.
 24. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 23 further comprising a second different metal “N_(n)”, where n is greater than zero and no greater than
 5. 25. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 24 further comprising a third different metal “R_(r)”, where r is greater than zero and no greater than
 5. 26. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 23, the at least one electron-withdrawing group having a molecular weight less than
 200. 27. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 23, the at least one electron-withdrawing surface group having a carbon chain length no greater than
 4. 28. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 23, the at least one electron withdrawing group having being selected from the group consisting of Cl, Br, BO₃, SO₄, PO₄, CH3COO, C₂O4, and C₆H₅O₇.
 29. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 23 further comprising the non-soluble solid metal oxide being tin oxide.
 30. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 23 further comprising the non-soluble solid metal oxide being iron oxide.
 31. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 23, the non-soluble solid metal oxide having a spherical morphology.
 32. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 23, the non-soluble solid metal oxide having an elongated morphology.
 33. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 23, the non-soluble solid metal oxide having a plate morphology.
 34. A battery electrode non-soluble solid metal oxide nanomaterial according to claim 23, wherein the non-soluble solid metal oxide is configured as an anode. 